High-voltage level-shifter architectures that provide galvanic coupling between low/high-voltage domains while simultaneously enabling high speed operation, low static current consumption and high reliability under a myriad of environmental circumstances including electromagnetic interference as well as process, voltage and temperature variations.
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5. A voltage level-shifter circuit comprising:
low-voltage domain circuitry configured to generate a voltage input signal with reference to a low-voltage domain ground node;
high-voltage domain circuitry capacitively coupled to the low-voltage domain circuitry and configured to generate a voltage output signal, with reference to a high-voltage domain common node, that corresponds to a level-shifted version of the voltage input signal;
wherein the high-voltage domain circuitry comprises charge amplifier circuitry and latch circuitry,
wherein the charge amplifier circuitry is configured to receive as input the voltage input signal and to drive the latch circuitry to generate the voltage output signal; and
wherein the voltage level-shifter circuit further comprises phase correction circuitry configured to dampen oscillations at nodes of the latch circuitry and overvoltage protection circuitry configured to protect the voltage level-shifter circuit from excess voltage, wherein the phase correction circuitry comprises a resistor-capacitor network coupled between an output of the latch circuitry and inputs of the overvoltage protection circuitry.
4. A voltage level-shifter circuit comprising:
low-voltage domain circuitry configured to generate a voltage input signal with reference to a low-voltage domain ground node;
high-voltage domain circuitry capacitively coupled to the low-voltage domain circuitry and configured to generate a voltage output signal, with reference to a high-voltage domain common node, that corresponds to a level-shifted version of the voltage input signal;
wherein the high-voltage domain circuitry comprises charge amplifier circuitry and latch circuitry,
wherein the charge amplifier circuitry is configured to receive as input the voltage input signal and to drive the latch circuitry to generate the voltage output signal; and
wherein the voltage level-shifter circuit further comprises bit-mismatch corrective circuitry configured to enforce the voltage output signal to a value that corresponds to the level-shifted version of the voltage input signal, wherein the bit-mismatch corrective circuitry comprises:
sampling circuitry configured to sample the voltage output signal;
clock circuitry configured to control the sampling circuit to sample the voltage output signal at a particular rate; and
comparator circuitry configured to compare an instant logic level of the voltage input signal with a sampled logic level of the voltage output signal, and to output a bit-correction signal to the low-voltage domain circuitry to enforce the voltage output signal to the value that corresponds to the level-shifted version of the voltage input signal.
1. A voltage level-shifter circuit comprising:
low-voltage domain circuitry configured to generate a voltage input signal with reference to a low-voltage domain ground node;
high-voltage domain circuitry capacitively coupled to the low-voltage domain circuitry and configured to generate a voltage output signal, with reference to a high-voltage domain common node, that corresponds to a level-shifted version of the voltage input signal;
wherein the high-voltage domain circuitry comprises charge amplifier circuitry, latch circuitry, and feedback circuitry,
wherein the charge amplifier circuitry is configured to receive as input the voltage input signal and to drive the latch circuitry to generate the voltage output signal,
wherein the feedback circuitry is configured to generate a slope detection signal in response to an erroneous condition at the latch circuitry, and
wherein the voltage level-shifter circuit further comprises common mode rejection circuitry configured to suppress propagation of a common mode error signal to the latch circuitry, wherein the common mode rejection circuitry comprises first clamp circuitry coupled to a control terminal of a first transistor of the charge amplifier circuitry and configured to pull the control terminal of the first transistor to a voltage potential of the high-voltage domain common node in response to the slope detection signal, and second clamp circuitry coupled to a control terminal of a second transistor of the charge amplifier circuitry and configured to pull the control terminal of the second transistor to the voltage potential of the high-voltage domain common node in response to the slope detection signal.
2. The voltage level-shifter circuit of
a first capacitor coupled to an output of a first inverter of the low-voltage domain circuitry,
a second capacitor coupled to an output of a second inverter of the low-voltage domain circuitry and configured to capacitively couple the high-voltage domain circuitry to the low-voltage domain circuitry;
a first transistor including a control terminal coupled to the first capacitor and a first terminal of a first resistor, a source/drain terminal coupled to a first node of the latch circuitry, and a drain/source terminal coupled to a second terminal of the first resistor and the high-voltage domain common node; and
a second transistor including a control terminal coupled to the second capacitor and a first terminal of a second resistor, a source/drain terminal coupled to a second node of the latch circuitry, and a drain/source terminal coupled to a second terminal of the second resistor and the high-voltage domain common node.
3. The voltage-level shifter circuit of
overvoltage protection circuitry configured to protect the voltage level-shifter circuit from excess voltage.
6. The voltage level-shifter circuit of
7. The voltage level-shifter circuit of
8. The voltage level-shifter circuit of
buffer circuitry coupled at an input terminal to a node of the latch circuitry and configured to generate at an output terminal the voltage output signal with reference to the high-voltage domain common node.
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High-voltage level-shifters may be used in applications where so-called high-side gate drivers are configured to drive internal (on-chip) or external (off-chip) power transistors. As an example, high-voltage level-shifters may be used in automotive applications where the trend towards increasing battery voltages (e.g., 12V->48V) is apparent. As such, high-voltage level-shifters have significant importance in motor bridge, ignition and direct injection systems for example, as well as DC-DC convertor circuits and many other automotive and non-automotive applications.
The present disclosure is directed to high-voltage level-shifter circuitry and methods that provide galvanic coupling between low-voltage and high-voltage domains while simultaneously enabling high speed operation, low static power consumption and high reliability under a myriad of environmental conditions including electromagnetic interference as well as process, voltage and temperature variations.
As an example implementation of the aspects of the present disclosure, a voltage level-shifter circuit may include or comprise latch circuitry configured to store an output bit that is a level-shifted version of an input bit, and charge amplifier circuitry configured to receive as input the input bit and, in response, to drive the latch circuitry to store the output bit that is the level-shifted version of the input bit.
As another example implementation of the aspects of the present disclosure, a voltage level-shifter circuit may include or comprise low-voltage domain circuitry that is configured to generate voltage input signals with reference to a low-voltage domain ground node, and high-voltage domain circuitry that is capacitively coupled to the low-voltage domain circuitry and that is configured to generate voltage output signals, with reference to a high-voltage domain common node, that correspond to a level-shifted version of the voltage input signals, wherein the high-voltage domain circuitry comprises charge amplifier circuitry and latch circuitry, and wherein the charge amplifier circuitry is configured to receive as input the voltage input signals and to drive the latch circuitry to generate the voltage output signals.
As another example implementation of the aspects of the present disclosure, a method may include or comprise, by charge amplifier circuitry of a voltage level-shifter circuit, receiving as input an input bit from low-voltage domain circuitry of the voltage level-shifter circuit and, in response, driving latch circuitry of the voltage level-shifter circuit to store an output bit that is a level-shifted version of the input bit.
As another example implementation of the aspects of the present disclosure, a voltage level-shifter circuit may include or comprise low-voltage domain circuitry that is configured to generate voltage input signals with reference to a low-voltage domain ground node, high-voltage domain circuitry that is capacitively coupled to the low-voltage domain circuitry and that is configured to generate voltage output signals, with reference to a high-voltage domain common node, that correspond to a level-shifted version of the voltage input signals, and correction control circuitry that is coupled in a feedback loop between the low-voltage domain circuitry and the high-voltage domain circuitry, wherein the high-voltage domain circuitry comprises charge amplifier circuitry that is configured to receive as input the voltage input signals and to drive the latch circuitry to generate the voltage output signals based on the voltage input signals, and wherein the correction control circuitry is configured to receive as input the voltage output signals and to drive the low-voltage domain circuitry to generate the voltage input signals based on the voltage output signals.
As another example implementation of the aspects of the present disclosure, a voltage level-shifter circuit may include or comprise latch circuitry configured to store an output bit that is a level-shifted version of an input bit, and feedback circuitry configured to restore the output bit to the level-shifted version of the input bit responsive to logic state change in the output bit absent logic state change in the input bit.
The details of one or more examples are set forth in the accompanying drawings and the description below. Other features, objects, and advantages will be apparent from the description and drawings, and from the claims.
Some high-voltage level-shifter (HVLSH) architectures may leverage two-stage or three-stage designs that include a first pseudo-differential stage with low-voltage (LV) components (e.g., supply/bias voltages<5V), from the core domain, a second stage with medium-voltage (MV) components (e.g., 5V<supply/bias voltages<12V), such as double-diffused isolation transistors (DMOS transistors) that operate at voltages above core voltage, and a third stage with high-voltage (HV) components (e.g., supply/bias voltages>12V) that operate at voltages even further above core voltage. In such architectures, the third stage is in general configured to reconstruct a signal bit that is received from the first stage and that in turn is fed into a high-side gate driver as a control signal.
Some HVLSH architectures may also leverage DC-coupled or galvanic-coupled signal paths to HV components via capacitive coupling, although transformer-based coupling is possible. When DC-coupling is used, HV DMOS transistors for example are taken as either isolation transistors or directly as high-side driving transistors. One disadvantage of such an architecture is relatively high power consumption due to non-zero static DC currents at both the LV and HV sides of the architecture. It is contemplated that the DC current flow can be avoided or minimized by design, although at a cost of substantially increased chip area requirements, using at least four DMOS transistors (e.g., two P-DMOS and two N-DMOS) as isolating devices and some additional circuitry.
Another disadvantage associated with DC-coupled level-shifter architectures is their inability to “drive downwards” or, equivalently, to shift towards negative voltage domains. This includes temporally short “under-voltage” states that might occur due to inductive behavior of wires and connections as well as permanent negative voltage shifts. From flexibility and efficiency perspectives, galvanic-coupled level-shifter architectures are more advantageous than DC-coupled level-shifter architectures
However, a disadvantage for both DC-coupled or galvanic-coupled architectures lies in a more or less reduced robustness with respect to faulty switching and bit-flipping in the HV circuitry. This can be fatal in power applications, since large cross-currents in driven power transistors can thermally destroy a chip or the discrete switching element, or could lead to a safety critical event like inadvertent activation of a switching element which may be contrary to the provisions of various standards, such as ISO 26262. Such cross-currents should be avoided and/or quickly corrected to maintain the switching element at a safe operating point, although unwanted logic state changes in level-shifter circuitry as a whole should be avoided. Yet another disadvantage of some HVLSH architectures is that they do not support different voltage swings in the LV and HV domains, i.e., (VDDA−VSSA)≠(VDDB−VSSB). The high-voltage level-shifter circuitry and methods of present disclosure solve many of these and other issues that plague some HVLSH architectures.
In particular, the present disclosure is directed to high-voltage level-shifter circuitry and methods that provide galvanic coupling between LV and HV domains while simultaneously enabling high speed operation, low static power consumption and high reliability under a myriad of environmental conditions including electromagnetic interference (EMI) as well as process, voltage and temperature (PVT) variations. As such, the features or aspects of the present disclosure, not merely limited to the implementation-specific examples discussed throughout, solve many of the issues that plague some HVLSH architectures, and do so in an efficient and cost-friendly manner realized in part due to the limited usage of high voltage devices (e.g., DMOS transistors).
For example, the features or aspects of the present disclosure may confer the following advantages: increased area and power efficiencies (e.g., ˜0.005 μm2 in 120 nm power technology, ˜1 nA DC current); fast switching speeds (e.g., ˜10-20 nanoseconds or better); no need for DMOS transistors that introduce parasitic elements like thyristors, diodes, and capacitances; robustness against data loss, fast switching transients, and EMI; and supports different voltage swings in the LV and HV domains.
In the example of
In particular, and as discussed in more detail below, charge amplifier circuitry 108 is configured such that only the change or transition of input bit 106 is processed in high-voltage domain 110. As such, level-shifter circuitry 100 is substantially less prone to EMI and PVT variations as compared to some HVLSH architectures. However, a common mode error signal for example may still propagate from low-voltage domain 104 to high-voltage domain 110 and corrupt output bit 116. Accordingly, it is contemplated that level-shifter circuitry 100 may further include feedback circuitry 118 (but not necessarily, as indicated by intermittent line in
In
For a high-to-low transition of input bit 106, the combination of capacitor 216, resistor 212 and transistor 208 acts as a charge amplifier for the two inputs % outputs of HV latch 202, where the output of inverter 220 (labeled node B in
While voltage level-shifter circuitry 100 as shown in
In particular,
As another example, it is contemplated that level-shifter circuitry 100 may be configured to exhibit a NOR-gate 304 (upper right side of
Transistors 308 and 310 are used to “clamp” the erroneous common mode signal at the gate nodes of transistors 208 and 210 and prevent transistors 208 and 210 from passing the erroneous common mode signal to the inputs/outputs of HV latch 202. This reliability feedback mechanism as realized by feedback circuitry 118 (see
But still, for ASIL-D and other highly secure applications, for example, it is contemplated that a bit error detection scheme may be implemented to further improve reliability and bit error rate at the output of level-shifter circuitry 100 as shown in
In particular,
In this example, level-shifter circuitry 100 may further be configured to exhibit an AND-gate 506 or a similar digital modulating block that “senses” the state (i.e., logic 0/1) at the output of level-shifter circuitry 100, where output bit 116 is ultimately provided as input to a high-side gate driver 508 that in turn is configured to drive a power transistor 510 as shown in
Next, assuming that output bit 116 is at logic 1 to continue with the example, a monoflop 516 or similar filtering device of level-shifter circuitry 100 will detect or demodulate the logic 1 and pass the signal (logic 1, or logic 0 in a different example) to the node (node G in
It is contemplated that the features or aspects of level-shifter circuitry 100 as shown and discussed in the context of
For example,
For example,
Next, assuming that output bit 116 is at logic 1, monoflop 704 will detect or demodulate the “high” duty cycle signal and pass the signal as a logic 1 (or logic 0 in a different example) to an output node (node G in
In particular,
After another finite delay, the signal at the input of monoflop 704 (see signal at node F in
One of ordinary skill in the art will understand that many benefits and advantages flow from high-voltage level-shifter circuitry 100 as configured and/or arranged in a manner as discussed in the context of
A voltage level-shifter circuit comprising: latch circuitry configured to store an output bit that is a level-shifted version of an input bit; and charge amplifier circuitry configured to receive as input the input bit and, in response, to drive the latch circuitry to store the output bit that is the level-shifted version of the input bit. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
The circuit of Example 1, wherein the charge amplifier circuitry comprises a first signal branch and a second signal branch, and wherein each one of the first signal branch and the second signal branch comprises a capacitor, a resistor and a transistor arranged in a topology to function as a charge amplifier for a corresponding one node of the latch circuitry. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
The circuit of any one of Examples 1-2, further comprising: overvoltage protection circuitry configured to protect the voltage level-shifter circuit from excess voltage. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
The circuit of any one of Examples 1-3, further comprising: common mode rejection circuitry configured to suppress propagation of a common mode error signal to the latch circuitry. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
The circuit of any one of Examples 1-4, further comprising: bit-mismatch corrective circuitry configured to enforce the output bit to a value that corresponds to the level-shifted version of the output bit. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
The circuit of any one of Examples 1-5, further comprising: phase correction circuitry configured to dampen oscillations at nodes of the latch circuitry. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
A voltage level-shifter circuit comprising: low-voltage domain circuitry that is configured to generate voltage input signals with reference to a low-voltage domain ground node; and high-voltage domain circuitry that is capacitively coupled to the low-voltage domain circuitry and that is configured to generate voltage output signals, with reference to a high-voltage domain common node, that correspond to a level-shifted version of the voltage input signals; wherein the high-voltage domain circuitry comprises charge amplifier circuitry and latch circuitry, and wherein the charge amplifier circuitry is configured to receive as input the voltage input signals and to drive the latch circuitry to generate the voltage output signals.
The circuit of Example 7, wherein the charge amplifier circuitry comprises: a first capacitor that is coupled to an output of a first inverter of the low-voltage domain circuitry, and a second capacitor that is coupled to an output of a second inverter of the low-voltage domain circuitry, to capacitively couple the high-voltage domain circuitry to the low-voltage domain circuitry; a first transistor that includes a control terminal that is coupled to the first capacitor and a first terminal of a first resistor, a source/drain terminal that is coupled to a first node of the latch circuitry, and a drain/source terminal that is coupled to a second terminal of the first resistor and the high-voltage domain common node; and a second transistor that includes a control terminal that is coupled to the second capacitor and a first terminal of a second resistor, a source/drain terminal that is coupled to a second node of the latch circuitry, and a drain/source terminal that is coupled to a second terminal of the second resistor and the high-voltage domain common node.
The circuit of any one of Examples 7-8, further comprising: overvoltage protection circuitry that is configured to protect the voltage level-shifter circuit from excess voltage, wherein the overvoltage protection circuitry comprises first clamp circuitry that is coupled to a control terminal of a first transistor of the charge amplifier circuitry and that is configured to limit magnitude of voltage at the control terminal of the first transistor, and second clamp circuitry that is coupled to a control terminal of a second transistor of the charge amplifier circuitry and that is configured to limit magnitude of voltage at the control terminal of the second transistor.
The circuit of any one of Examples 7-9, further comprising: common mode rejection circuitry configured to suppress propagation of a common mode error signal to the latch circuitry, wherein the overvoltage protection circuitry comprises first clamp circuitry that is coupled to a control terminal of a first transistor of the charge amplifier circuitry and that is configured to pull the control terminal of the first transistor to a voltage potential of the high-voltage domain common node, and second clamp circuitry that is coupled to a control terminal of a second transistor of the charge amplifier circuitry and that is configured to pull the control terminal of the second transistor to the voltage potential of the high-voltage domain common node.
The circuit of any one of Examples 7-10, further comprising: bit-mismatch corrective circuitry configured to enforce the voltage output signals to a value that corresponds to the level-shifted version of the voltage input signals, wherein the bit-mismatch corrective circuitry comprises: sampling circuitry configured to sample the voltage output signals; clock circuitry configured to control the sampling circuit to sample the voltage output signals at a particular rate; and comparator circuitry configured to compare an instant logic level of the voltage input signals with a sampled logic level of the voltage output signals, and to output a bit-correction signal to the low-voltage domain circuitry that is coupled into the high-voltage domain circuitry to enforce the voltage output signals to the value that corresponds to the level-shifted version of the voltage input signals.
The circuit of any one of Examples 7-11, further comprising: phase correction circuitry configured to dampen oscillations at nodes of the latch circuitry, wherein the phase correction circuitry comprises a resistor-capacitor network that is coupled between an output of the latch circuitry and inputs of the overvoltage protection circuitry.
The circuit of any one of Examples 7-12, wherein the low-voltage domain circuitry comprises a first inverter that is coupled in series with a second inverter, and wherein the first inverter and the second inverter are configured to generate the voltage input signals.
The circuit of any one of Examples 7-13, wherein the latch circuitry comprises a first latch inverter and a second latch inverter, wherein an output of the first latch inverter is coupled to an input of the second latch inverter at a first node of the latch circuitry, and an output of the second latch inverter is coupled to an input of the first latch inverter at a second node of the latch circuitry.
The circuit of any one of Examples 7-14, further comprising: buffer circuitry that is coupled at an input terminal to a node of the latch circuitry and that is configured to generate at an output terminal the voltage output signals with reference to the high-voltage domain common node.
A method comprising: by charge amplifier circuitry of a voltage level-shifter circuit, receiving as input an input bit from low-voltage domain circuitry of the voltage level-shifter circuit and, in response, driving latch circuitry of the voltage level-shifter circuit to store an output bit that is a level-shifted version of the input bit.
The method of Example 16, further comprising: by overvoltage protection circuitry of the voltage level-shifter circuit, preventing the voltage level-shifter circuit from exposure to excess voltage.
The method of any one of Examples 16-17, further comprising: by common mode rejection circuitry of the voltage level-shifter circuit, suppressing propagation of a common mode error signal to the latch circuitry.
The method of any one of Examples 16-18, further comprising: by bit-mismatch corrective circuitry of the voltage level-shifter circuit, enforcing the output bit to a value that corresponds to the level-shifted version of the output bit.
The method of any one of Examples 16-19, further comprising: by phase correction circuitry of the voltage level-shifter circuit, dampening oscillations at nodes of the latch circuitry.
A voltage level-shifter circuit comprising: low-voltage domain circuitry that is configured to generate voltage input signals with reference to a low-voltage domain ground node: high-voltage domain circuitry that is capacitively coupled to the low-voltage domain circuitry and that is configured to generate voltage output signals, with reference to a high-voltage domain common node, that correspond to a level-shifted version of the voltage input signals; and correction control circuitry that is coupled in a feedback loop between the low-voltage domain circuitry and the high-voltage domain circuitry; wherein the high-voltage domain circuitry comprises charge amplifier circuitry that is configured to receive as input the voltage input signals and to drive the latch circuitry to generate the voltage output signals based on the voltage input signals, and wherein the correction control circuitry is configured to receive as input the voltage output signals and to drive the low-voltage domain circuitry to generate the voltage input signals based on the voltage output signals.
The circuit of Example 21, wherein the charge amplifier circuitry comprises a first signal branch and a second signal branch, and wherein each one of the first signal branch and the second signal branch comprises a capacitor, a resistor and a transistor arranged in a topology to function as a charge amplifier for a corresponding one node of the latch circuitry.
The circuit of any one of Examples 21-22, wherein the capacitor and the resistor of each one of the first signal branch and the second signal are arranged in a topology to function as a high pass filter.
A voltage level-shifter circuit comprising: latch circuitry configured to store an output bit that is a level-shifted version of an input bit; and feedback circuitry configured to restore the output bit to the level-shifted version of the input bit responsive to logic state change in the output bit absent logic state change in the input bit. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
The circuit of Example 24, wherein the feedback circuitry comprises oscillator circuitry that is configured to operate in a low-voltage domain of the voltage level-shifter circuit while the latch circuitry is configured to operate in a high-voltage domain of the voltage level-shifter circuit, and wherein the oscillator circuitry is configured to output a signal at a frequency that represents resolution for the feedback circuitry to monitor logic state of the output bit and input bit. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
The circuit of any one of Examples 24-25, wherein the feedback circuitry comprises oscillator circuitry that is configured to operate in a high-voltage domain of the voltage level-shifter circuit while the latch circuitry is configured to operate in the high-voltage domain of the voltage level-shifter circuit, and wherein the oscillator circuitry is configured to output a signal at a frequency that represents resolution for the feedback circuitry to monitor logic state of the output bit and input bit. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
The circuit of any one of Examples 24-26, wherein the feedback circuitry is configured to monitor logic state of the input bit and the output bit at a frequency that is a function of an oscillator clock signal. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
The circuit of any one of Examples 24-27, wherein the feedback circuitry is configured to determine a mismatch between logic state of the input bit and logic state of the output bit and control the latch circuitry to store the output bit that is the level-shifted version of the input bit. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
The circuit of any one of Examples 24-28, further comprising charge amplifier circuitry configured to receive as input the input bit and, in response, to drive the latch circuitry to store the output bit that is the level-shifted version of the input bit. Although not so limited, such an example implementation is consistent with that shown and described in connection with at least
Various examples of the disclosure have been described. Any combination of the described systems, operations, or functions is contemplated. These and other examples are within the scope of the following claims.
Wachter, Franz, Ullmann, Igor, Kalt, Andreas
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